American Journal of BioScience 2015; 3(6): 267-277 Published online December 21, 2015 (http://www.sciencepublishinggroup.com/j/ajbio) doi: 10.11648/j.ajbio.20150306.20 ISSN: 2330-0159 (Print); ISSN: 2330-0167 (Online)

Comparative Physicochemical Evaluation of Biofield Treated Phosphate Buffer Saline and Hanks Balanced Salt Medium

Mahendra Kumar Trivedi1, Alice Branton

1, Dahryn Trivedi

1, Gopal Nayak

1,

Rakesh Kumar Mishra2, Snehasis Jana

2, *

1Trivedi Global Inc., Henderson, USA 2Trivedi Science Research Laboratory Pvt. Ltd., Bhopal, Madhya Pradesh, India

Email address: publication@trivedisrl.com (S. Jana)

To cite this article: Mahendra Kumar Trivedi, Alice Branton, Dahryn Trivedi, Gopal Nayak, Rakesh Kumar Mishra, Snehasis Jana. Comparative Physicochemical

Evaluation of Biofield Treated Phosphate Buffer Saline and Hanks Balanced Salt Medium. American Journal of BioScience.

Vol. 3, No. 6, 2015, pp. 267-277. doi: 10.11648/j.ajbio.20150306.20

Abstract: Phosphate buffer saline (PBS) has numerous biological and pharmaceutical applications. Hank buffer salt (HBS) has been used as a medium for tissue culture applications. This research study was aimed to investigate the influence of Mr. Trivedi’s biofield energy treatment on physicochemical properties of the PBS and HBS. The study was executed in two group’s i.e. control and treated. The control group was kept aside as control and treated group had received the biofield energy treatment. The control and treated samples were further characterized by X-ray diffraction (XRD), differential scanning calorimetry (DSC), thermogravimetric analysis (TGA), and Fourier transform infrared (FT-IR) spectroscopy. The XRD analysis indicated the increase in crystallite size by 5.20% in treated PBS as compared to the control. Similarly, the treated HBS also showed increase in crystallite size by 3.20% with respect to the control. Additionally, the treated PBS showed an increase in Bragg’s angle (2θ) as compared to the control sample. However, a decrease in Bragg’s angle of XRD peaks of the treated sample was noticed in the treated HBS. The DSC analysis of the control PBS showed melting temperature at 224.84°C; however melting temperature was not observed in the treated sample. However, DSC analysis of the treated HBS showed an increase in melting temperature (152.83°C) in comparison with the control (150.60°C). Additionally, the latent heat of fusion of the treated HBS was increased substantially by 108.83% as compared to the control. The TGA thermogram of the treated PBS showed an increase in onset of thermal degradation (212°C) as compared to the control (199°C). Whereas, the treated HBS showed less weight loss comparing with the control sample. This indicated the increase in thermal stability of the both the treated PBS and HBS samples. The FT-IR spectroscopic analysis of treated PBS showed alterations in the frequency of the functional groups such as O-H, C-H, P=O, O=P-OH, and P-OH as compared to the control. Additionally, the FT-IR spectrum of the treated HBS showed increase in frequency of calcium chloride phase (1444→1448 cm-1) as compared to the control sample. Altogether, it was observed that biofield energy treatment had caused physical, thermal and spectral changes in the treated samples as compared to the control. It is assumed that biofield energy treated PBS and HBS could be a good prospect for biological and tissue culture applications.

Keywords: Phosphate Buffer Saline, Hank Buffer Salt, Biofield Energy Treatment, X-ray Diffraction, Thermal Analysis

1. Introduction

Phosphate buffer saline (PBS) is a buffer solution commonly used in biological research. It is mainly a water-based salt solution containing sodium phosphate and sodium chloride. PBS is known to be isotonic to the biological cells, hence it has many applications. It has been used in laboratory protocols for dilutions, washing cell suspensions,

rinsing culture flaks and plates as well as additives to cell culture media [1-6]. PBS is commercially available in different formulation with calcium and magnesium (+/+ PBS) or without (–/– PBS) [7]. Lichtenauer et al. reported that PBS might have an influence on the human peripheral mononuclear cells under different culture conditions. They elaborated that these alterations of extracellular conditions might influence several functions such as secretion of cytokines, proliferative responses and cell death [8]. Moreover, PBS-based buffers

268 Mahendra Kumar Trivedi et al.: Comparative Physicochemical Evaluation of Biofield Treated Phosphate Buffer Saline and Hanks Balanced Salt Medium

have been used in pharmaceutical industries for assessing the drug release, drug stability as well as buffer for high-performance liquid chromatography (HPLC) [9]. Additionally, PBS has also been used as a buffer in the microbial fuel cells to maintain the pH conditions and solution conductivity [10]. The salt solution has been used to maintain the medium within the physiological pH range. This is also used to maintain the intracellular and extracellular osmotic balance. Hank’s balanced salt (HBS) solution is used in cell culture applications. It is designed for use in cells maintained with less CO2 environment or CO2 free environment [11].

Stability of buffer solution is an important requirement for its intended uses in pharmaceutical and biological applications. It was reported that stability of buffer solution can be affected by temperature, chemical, light, etc. [12]. Thus, it is envisaged that stability of buffer solutions such as PBS and HBS could be improved using some alternative methods. Recently, biofield energy treatment was used as a lucrative method for physicochemical modifications of various materials.

Biofield energy therapies are considered under complementary and alternative medicine (CAM). These kind of therapies contains practices based on subtle energy fields, and it is envisaged that human beings are permeated with a subtle form of energy [13]. It is believed that biofield therapies are effective in reducing stress such as daily life stress and stress of patients receiving terminal care [14]. It was reported that healing practitioners can channel the energy to the patients and confer positive results. Therefore, it is suggested that human beings have the ability to harness the energy from the environment/Universe and can transmit into any object (living or non-living) around the Globe. The object(s) will always receive the energy and responding in a useful manner that is called biofield energy. Moreover, biofield energy treatment that comes under the category of CAM therapies have been approved by the prestigious National Institute of Health (NIH)/The National Centre for Complementary and Alternative Medicine (NCCAM), as an alternative treatment in the healthcare sector [15]. Mr. Mahendra Kumar Trivedi is a well-known healer of biofield energy who can alter the physicochemical properties of materials such as metals [16], organic compound [17], drugs [18], and polymers [19]. Additionally, the biofield energy treatment is also known as The Trivedi effect® has improved the production in the field of agriculture [20] and altered the phenotypic characteristics of pathogenic microbes [21]. Therefore, after conceiving the above-mentioned outcomes of biofield energy treatment, and properties of PBS and HBS, authors, have planned to investigate the impact of biofield energy on physicochemical properties of these buffers.

2. Materials and Methods

Phosphate buffer saline (PBS) and Hank’s balanced salt (HBS) solution were procured from Himedia Laboratories, India, and the samples were divided into two parts. The one part was kept aside as a control sample, while the other part was subjected to Mr. Trivedi’s unique biofield energy

treatment and labelled as treated sample. The treated group was in sealed pack and handed over to Mr. Trivedi for biofield energy treatment under standard laboratory conditions. Mr. Trivedi gave the energy treatment through his energy transmission process to the treated sample without touching the sample. The control and treated samples were characterized by different analytical techniques such as X-ray diffraction, differential scanning calorimetry, thermogravimetric analysis, and Fourier transform infrared spectroscopy.

2.1. X-ray Diffraction (XRD)

XRD analysis of control and treated samples (PBS and HBS) were evaluated using X-ray diffractometer system, Phillips, Holland PW 1710 which consist of a copper anode with nickel filter. XRD system had a radiation of wavelength 1.54056 Å. The average crystallite size (G) was computed using formula:

G = kλ/(bCosθ) (1)

Here, λ is the wavelength of radiation used, b is full-width half-maximum (FWHM) of peaks and k is the equipment constant (=0.94). Percentage change in average crystallite size was calculated using following formula:

Percentage change in crystallite size = [(Gt-Gc)/Gc] ×100 (2)

Where, Gc and Gt are denoted as crystallite size of control and treated powder samples, respectively.

2.2. Differential Scanning Calorimetry (DSC)

The control and treated samples (PBS and HBS) were analyzed using Pyris-6 Perkin Elmer DSC at a heating rate of 10°C/min and the air was purged at a flow rate of 5 mL/min. The predetermined amount of sample was kept in an aluminum pan and closed with a lid. A reference sample was prepared using a blank aluminum pan. The percentage change in latent heat of fusion was calculated using following equations:

% Change in latent heat of fusion

= [∆H Treated - ∆H Control]/ ∆H Control × 100 (3)

Where, ∆H Control and ∆H Treated are the latent heat of fusion of control and treated samples, respectively.

2.3. Thermogravimetric Analysis-Differential Thermal

Analysis (TGA-DTA)

A Mettler Toledo simultaneous TGA and differential thermal analyzer (DTA) was used to investigate the thermal stability of control and treated samples (PBS and HBS). The rate of heating was 5°C/min and samples were heated in the range of room temperature to 400°C under air atmosphere.

2.4. FT-IR Spectroscopy

The FT-IR spectra were recorded on Shimadzu’s Fourier transform infrared spectrometer (Japan) with the frequency range of 4000-500 cm-1.

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3. Results and Discussion

3.1. X-ray Diffraction

X-ray diffraction studies were conducted to investigate the crystalline nature of the control and treated samples. XRD diffractogram of control and treated PBS are presented in Fig. 1. The XRD diffractogram of the control PBS showed intense crystalline peaks at Bragg’s angle 27.31º, 31.62º, 45.36º, 45.50º, 56.39º, 66.16º, and 75.23º. However, the treated PBS showed the occurrence of intense peaks at Bragg’s angle 27.30º, 31.65º, 45.40º, 45.54º, 56.43º, 66.19º and 75.26º. The result indicated an increase in Bragg’s angle at 31.62→31.65, 45.36º→45.40º, 45.50º→45.54º, 56.39º→56.43º,

66.16º→66.19º, and 75.23º→75.26º in the treated sample as compared to the control. It was reported that presence of tensile stress in molecules might cause an increase in Bragg’s angle of the samples. Thus, it is assumed that biofield energy treatment might cause the emergence of tensile stress in treated PBS molecules that led to increase in Bragg’s angle of the sample as compared to the control. The crystallite size was computed from XRD data of control and treated PBS and results are presented in Fig. 2. The crystallite size of the control PBS was 107.95 nm, and it was increased to 113.56 nm in the treated sample. The result demonstrated 5.20% increase in crystallite size of the treated sample as compared to the control.

Figure 1. XRD diffractograms of the control and treated phosphate buffer saline.

270 Mahendra Kumar Trivedi et al.: Comparative Physicochemical Evaluation of Biofield Treated Phosphate Buffer Saline and Hanks Balanced Salt Medium

Figure 2. Crystallite size of the control and treated phosphate buffer saline

and hanks balanced salt.

XRD diffractogram of the control and treated HBS are depicted in Fig. 3. The XRD diffractogram of the control sample showed intense crystalline peaks at Bragg’s angle at 27.35º, 28.33º, 31.69º, 31.78º, 45.43º, 56.46º, 66.22º, and

75.26º. However, the treated sample showed XRD peaks at Bragg’s angle 27.31º, 28.31º, 31.65º, 31.75º, 45.41º, 56.43º, 66.20º and 75.27º. The result showed a decrease in Bragg’s angle of the treated sample 27.35º→27.31º, 28.33º→28.31º, 31.69º→31.65º, 31.78º→31.75º, 45.43º→45.41º, 56.46º→56.43º, and 66.22º→66.20º as compared to the control. Additionally, a significant decrease in XRD peak intensity was also observed with respect to the control sample. Inoue and Hirasawa demonstrated an interesting relationship between crystal morphology and XRD peak intensity of gypsum (CaSO4·2H2O). They elaborated that decrease in intensity of XRD peaks might change the crystal morphology of the gypsum samples [22]. Therefore, it is assumed that biofield treatment may led to change in crystal morphology of the treated HBS that might led to depression in the intensity of the XRD peak as compared to the control.

Figure 3. XRD diffractograms of the control and treated hank balanced salt.

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The crystallite size of the control HBS was 110.81 nm, and it was increased to 114.36 nm in the treated sample. The result suggested the increase in crystallite size by 3.20% in the treated HBS with respect to the control. The crystallite size is known as a group of molecules having orientation in the same plane. Researchers have shown that modulation in crystallite size directly governs the material properties. Grzmil et al. showed that calcination along with an increase in temperature causes a considerable increase in crystallite size of the materials [23]. Additionally, Jacob et al. during their studies on nano ceramic materials demonstrated that different treating temperature causes an increase in crystallite size [24, 25]. Thus, it is hypothesized that biofield treatment might provide thermal energy that led to the expansion of the crystallite size of the treated PBS and HBS salt as compared to the control.

3.2. DSC Characterization

DSC is a thermal analysis technique that is used to investigate the melting temperature, glass transition and latent heat of fusion of the materials. The DSC thermograms of control and treated PBS samples are presented in Fig. 4. The DSC thermogram of control PBS showed two endothermic peaks i.e. at 67.95 and 224.84°C. The first endothermic peak was due to some bound water in the sample and the second peak may be attributed to the melting of the disodium hydrogen phosphate in the sample. Whereas, the treated PBS showed endothermic peak at 63.39°C that was due to bound water in the sample. However, the second endothermic peak was disappeared in the treated sample that might be due to robust crystalline nature of the treated sample as compared to the control.

Figure 4. DSC thermograms of control and treated phosphate buffer saline.

272 Mahendra Kumar Trivedi et al.: Comparative Physicochemical Evaluation of Biofield Treated Phosphate Buffer Saline and Hanks Balanced Salt Medium

Figure 5. DSC thermograms of control and treated hank buffer salt.

DSC thermogram of the control and treated HBS are presented in Fig. 5. DSC thermogram of control HBS showed an endothermic transition at 150.60°C that may be due to melting temperature of the sample. However, the treated HBS showed an endothermic peak at 152.83°C, attributed to melting temperature of the sample. The increase in endothermic peak might be associated with an increase in thermal stability of the treated HBS. It was previously reported that increase in melting temperature could be correlated to increase in thermal stability [26]. The latent heat of fusion results were recorded from the DSC thermograms. The latent heat of fusion is regarded as heat absorbed during phase transition i.e. solid to the liquid phase of a material. The latent heat of fusion of the control sample was 9.06 J/g, and it was substantially increased to 18.92 J/g in the treated HBS. The result indicated 108.83% increase in the latent heat of

fusion of the treated HBS sample with respect to the control. Recently, biofield energy treatment had altered the latent heat of fusion of indole compound [16].

3.3. TGA Analysis

TGA analysis is a thermal technique that is used to measure the thermal decomposition, weight loss, volatilization, and oxidation in the samples. The TGA thermograms of the control and treated PBS are presented in Fig. 6. The TGA thermogram of the control PBS showed three-steps thermal degradation pattern. The first step thermal degradation commenced at around 199°C and terminated at around 220°C. The second step thermal decomposition began at around 221°C and terminated at around 246°C. Further, the third decomposition started at around 336°C and terminated at around 361°C. Contrarily, the TGA thermogram of the treated

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PBS showed one-step thermal degradation pattern. The thermal degradation began at around 212°C and terminated at around 270°C. The result showed that onset of thermal degradation of the treated PBS (212 °C) was higher as compared to the control (199°C). This may be attributed to increased thermal stability of the biofield energy treated PBS as compared to the control.

TGA thermogram of the control and treated HBS are presented in Fig. 7. The TGA thermogram of the control sample showed commencement of thermal degradation at around 180°C and it stopped at around 260°C. However, the treated sample showed thermal degradation at around 130°C and it terminated at around 237°C. The results indicated that the control and treated sample had lost 10.78 and 5.35%, respectively from its initial weight during the thermal

degradation process. DTG thermogram of the control and treated HBS are shown in Fig. 7. DTG thermogram of the control HBS showed maximum thermal decomposition temperature (Tmax) at 207.88. However, the treated HBS showed Tmax at 186.31°C. The result suggested that thermal weight loss in the treated sample was less as compared to the control. This may be regarded as the high thermal stability of the treated sample with respect to the control.

It was reported that crosslinking and conformational changes might induce thermal stability to gamma radiation treated polymer [27]. Therefore, it is assumed that biofield energy treatment might cause the crosslinking and conformational changes in the treated PBS and HBS molecules that leads to increase in thermal stability of the treated samples.

Figure 6. TGA thermograms of control and treated phosphate buffer saline.

274 Mahendra Kumar Trivedi et al.: Comparative Physicochemical Evaluation of Biofield Treated Phosphate Buffer Saline and Hanks Balanced Salt Medium

Figure 7. TGA thermograms of control and treated hanks balanced salt.

3.4. FT-IR Spectroscopy

FT-IR spectroscopy was used to evaluate the vibrational frequencies of different functional groups present in the samples. FT-IR spectra of the control and treated PBS are depicted in Fig. 8. The characteristic peaks observed in the region of 3373-3440 cm-1 were due to stretching vibration of

hydrogen bonded O-H group in disodium hydrogen phosphate in the control sample. However, the treated PBS showed these peaks in the region 3369-3440 cm-1. The P-OH symmetrical stretching vibration appeared in the region of 2813-2893 cm-1 in the control sample. While, in the treated PBS these peaks appeared at 2827-2879 cm-1. The PO-H symmetrical stretch was observed at 2327 cm-1 and it was shifted to 2337 cm-1 in

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the treated sample. Further, the PO-H bending peak was assigned at 954 cm-1 in the control PBS and in the treated sample it was appeared at 952 cm-1. It was reported that when a P-OH group exists with one P=O group, an additional broad peak appears in the region of 1750-1630 cm-1 [28]. Similarly, disodium hydrogen phosphate molecules present in control PBS exhibited stretching vibration peaks in the region of 1633-1716 cm-1. However, the treated sample showed these peaks at 1660-1745 cm-1. These peaks were attributed to O=P-OH deformation vibrations in the control and treated sample. The peaks at 1134-1344 cm-1 were might be due to P=O stretching vibrations and in the case of the treated sample these peaks were appeared at 1134-1361 cm-1. Additionally, the P-O stretching was observed at 1066 and 1068 cm-1 in the control and treated samples. The P-OH out of plane bending vibrations were appeared at 530 and 542 cm-1 in the control and treated samples [29]. Overall, the result showed decrease in frequency of stretching peaks such as 3373→3369, 2893→2879, and 1390→1361 cm-1 in the treated PBS as compared to the control. This might be due to decrease in

force constant of these O-H, C-H and P=O groups in the treated sample. However, the frequency of O=P-OH deformation and P-OH bending vibrations were increased (530→541 cm-1 and 1716→1745 cm-1) as compared to the control. It is assumed that biofield energy treatment might caused increase in force constant and strength of these bonds.

The FT-IR spectra of the control and treated HBS are presented in Fig. 9. The broad stretching vibration peak at 3242 cm-1 was due to –OH present in the calcium chloride of the control HBS. In treated sample, these peaks appeared at a higher frequency, 3392 cm-1 as compared to the control. The C-H stretching vibrations peaks were assigned in the region of 2895-2937 cm-1 in the control HBS, while the treated sample showed these peaks at 2879-2939 cm-1. A characteristic stretching peak of calcium chloride phase was evidenced at 1444 cm-1 in the control sample, but it was shifted to a higher frequency in the treated HBS, 1448 cm-1. This might be due to increase in force constant of this particular group as compared to the control sample.

Figure 8. FT-IR spectra of control and treated phosphate buffer saline.

276 Mahendra Kumar Trivedi et al.: Comparative Physicochemical Evaluation of Biofield Treated Phosphate Buffer Saline and Hanks Balanced Salt Medium

Figure 9. FT-IR spectra of control and treated hanks balanced salt.

4. Conclusion

In summary, the XRD results indicated increase in crystallite size by 5.20 and 3.20% in treated samples (PBS and HBS) as compared to the control. It is hypothesized that biofield treatment may provide thermal energy that caused increase in crystallite size with respect to the control samples (PBS and HBS). The DSC analysis showed disappearance of melting temperature in the treated PBS as compared to the control. This was perhaps due to rigid crystalline nature of the treated sample. However, the treated HBS (152.83°C) showed slight increase in the melting temperature with respect to the control (150.60°C). Additionally, the latent heat of fusion was increased substantially by 108.83% in the treated HBS sample, when compared with the control. The TGA analysis showed increase in thermal stability of the treated samples (PBS and HBS) as compared to the control. The FT-IR spectroscopic evaluation showed the alteration in frequency of functional

groups such as O-H, C-H, P=O, O=P-OH, and P-OH in the treated PBS. The FT-IR spectrum of the treated HBS showed some alteration in frequency of the calcium chloride phase (1444→1448 cm-1) of the treated sample as compared to the control. Overall, the results showed that biofield treatment has changed the physical, thermal and spectral properties of the treated samples (PBS and HBS) with respect to the control. It is assumed that good thermal stability of the treated samples might make them a good candidate for biological and tissue culture applications.

Abbreviations

PBS: Phosphate buffer saline; HBS: Hank buffer salt; XRD: X-ray diffraction; DSC: Differential scanning calorimetry; TGA: Thermogravimetric analysis; FT-IR: Fourier transform infrared.

American Journal of BioScience 2015; 3(6): 267-277 277

Acknowledgments

The authors wish to thank all the laboratory staff of MGV Pharmacy College, Nashik for their kind assistance during handling the various instrument characterizations. The authors would also like to thank Trivedi Science, Trivedi Master Wellness and Trivedi Testimonials for their support during the work.

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